Visualization of the lamina cribrosa using enhanced depth imaging spectral-domain optical coherence tomography.

PURPOSE To investigate whether the enhanced depth imaging technique (EDI) may improve the visualization of the lamina cribrosa using spectral-domain optical coherence tomography (SD-OCT). DESIGN Prospective observational case series. METHODS Images of the optic nerve were obtained in 10 normal subjects, 7 glaucoma suspects, and 18 glaucoma patients by positioning an SD-OCT in the usual fashion, as well as close enough to the eye to obtain an inverted representation of the fundus (EDI). In addition to these single line scans, approximately 65 sections were obtained within a 10 × 15-degree rectangle covering the optic nerve head using EDI. The "depth of signal" was measured as the distance from the optic cup surface and the point where the signal ended in both single line scan images. RESULTS Compared to the image obtained with the SD-OCT used in the usual fashion, images obtained with EDI provided larger depth of signal (728.04 ± 124.20 vs 368.79 ± 75.15 μm, P < .001) below the optic cup surface and better image contrast from the deep optic nerve; this facilitated the discrimination of the lamina cribrosa. In the en face image, the lamina cribrosa was visualized as a highly reflective plate containing multiple pores that corresponded with the color fundus photographs. CONCLUSION Using EDI SD-OCT, the full-thickness lamina cribrosa was clearly visualized in all eyes examined. This technique should facilitate the investigation on the lamina cribrosa in glaucoma, and may provide additional insight into the pathogenesis of glaucomatous optic neuropathy.

[1]  L. Dandona,et al.  Quantitative regional structure of the normal human lamina cribrosa. A racial comparison. , 1990, Archives of ophthalmology.

[2]  W. Green,et al.  The histology of human glaucoma cupping and optic nerve damage: clinicopathologic correlation in 21 eyes. , 1979, Ophthalmology.

[3]  G. Wollstein,et al.  Improved visualization of glaucomatous retinal damage using high-speed ultrahigh-resolution optical coherence tomography. , 2008, Ophthalmology.

[4]  B E Bouma,et al.  Elimination of depth degeneracy in optical frequency-domain imaging through polarization-based optical demodulation. , 2006, Optics letters.

[5]  Ruikang K. Wang,et al.  Use of a scanner to modulate spatial interferograms for in vivo full-range Fourier-domain optical coherence tomography. , 2007, Optics letters.

[6]  R. T. Hart,et al.  Deformation of the lamina cribrosa and anterior scleral canal wall in early experimental glaucoma. , 2003, Investigative ophthalmology & visual science.

[7]  Ian A Sigal,et al.  Biomechanics of the optic nerve head. , 2009, Experimental eye research.

[8]  Ruikang K. Wang,et al.  Fourier domain optical coherence tomography achieves full range complex imaging in vivo by introducing a carrier frequency during scanning , 2007, Physics in medicine and biology.

[9]  Julie Albon,et al.  Age related changes in the non-collagenous components of the extracellular matrix of the human lamina cribrosa , 2000, The British journal of ophthalmology.

[10]  J. Fleiss,et al.  Statistical methods for rates and proportions , 1973 .

[11]  Jost B Jonas,et al.  Anatomic relationship between lamina cribrosa, intraocular space, and cerebrospinal fluid space. , 2003, Investigative ophthalmology & visual science.

[12]  M. C. Leske,et al.  The Lens Opacities Classification System III. The Longitudinal Study of Cataract Study Group. , 1993, Archives of ophthalmology.

[13]  J. Jonas,et al.  Central corneal thickness, lamina cribrosa and peripapillary scleral histomorphometry in non-glaucomatous chinese eyes , 2010, Graefe's Archive for Clinical and Experimental Ophthalmology.

[14]  J. Jonas,et al.  Lamina cribrosa and peripapillary sclera histomorphometry in normal and advanced glaucomatous Chinese eyes with various axial length. , 2009, Investigative ophthalmology & visual science.

[15]  Julie Albon,et al.  Age-related compliance of the lamina cribrosa in human eyes , 1994 .

[16]  R L Radius,et al.  Anatomy of the lamina cribrosa in human eyes. , 1981, Archives of ophthalmology.

[17]  Iwona Gorczynska,et al.  Ultrahigh-speed optical coherence tomography for three-dimensional and en face imaging of the retina and optic nerve head. , 2008, Investigative ophthalmology & visual science.

[18]  A. H. Bunt,et al.  Orthograde and retrograde axoplasmic transport during acute ocular hypertension in the monkey. , 1977, Investigative ophthalmology & visual science.

[19]  G. Jeffery,et al.  Age-related changes in the thickness of the human lamina cribrosa , 2006, British Journal of Ophthalmology.

[20]  David J. Wilson,et al.  A comparison of optic nerve head morphology viewed by spectral domain optical coherence tomography and by serial histology. , 2010, Investigative ophthalmology & visual science.

[21]  F. Ferris,et al.  New visual acuity charts for clinical research. , 1982, American journal of ophthalmology.

[22]  W. Green,et al.  Optic nerve damage in human glaucoma. II. The site of injury and susceptibility to damage. , 1981, Archives of ophthalmology.

[23]  J. Jonas,et al.  Morphometry of the human lamina cribrosa surface. , 1991, Investigative ophthalmology & visual science.

[24]  Adnan Tufail,et al.  Repeatability of manual subfoveal choroidal thickness measurements in healthy subjects using the technique of enhanced depth imaging optical coherence tomography. , 2011, Investigative ophthalmology & visual science.

[25]  C. R. Ethier,et al.  Finite element modeling of optic nerve head biomechanics. , 2004, Investigative ophthalmology & visual science.

[26]  T. Tanishima,et al.  Axoplasmic flow during chronic experimental glaucoma. 1. Light and electron microscopic studies of the monkey optic nervehead during development of glaucomatous cupping. , 1978, Investigative ophthalmology & visual science.

[27]  R. Radius Anatomy of the optic nerve head and glaucomatous optic neuropathy. , 1987, Survey of ophthalmology.

[28]  井上 亮,et al.  Three-dimensional high-speed optical coherence tomography imaging of lamina cribrosa in glaucoma , 2011 .

[29]  M. C. Leske,et al.  The Lens Opacities Classification System III , 1993 .

[30]  B. Everitt,et al.  Statistical methods for rates and proportions , 1973 .

[31]  N. Levy,et al.  Displacement of optic nerve head in response to short-term intraocular pressure elevation in human eyes. , 1984, Archives of ophthalmology.

[32]  W. Andrzejewska,et al.  Age-related changes in the extracellular matrix of the human optic nerve head. , 1989, American journal of ophthalmology.

[33]  Zhongping Chen,et al.  Removal of a mirror image and enhancement of the signal-to-noise ratio in Fourier-domain optical coherence tomography using an electro-optic phase modulator. , 2005, Optics letters.

[34]  H. Quigley,et al.  Structural proteins of the neonatal and adult lamina cribrosa. , 1989, Archives of ophthalmology.

[35]  R. Spaide,et al.  Enhanced depth imaging spectral-domain optical coherence tomography. , 2008, American journal of ophthalmology.

[36]  R. Massof,et al.  Morphologic changes in the lamina cribrosa correlated with neural loss in open-angle glaucoma. , 1983, American journal of ophthalmology.

[37]  J. Jonas,et al.  Lamina cribrosa thickness and spatial relationships between intraocular space and cerebrospinal fluid space in highly myopic eyes. , 2004, Investigative ophthalmology & visual science.

[38]  R. T. Hart,et al.  Three-dimensional reconstruction of normal and early glaucoma monkey optic nerve head connective tissues. , 2004, Investigative ophthalmology & visual science.